Method of making wire gun

ABSTRACT

HAND HELD GUN FROM WHICH WIRE IS EJECTED FOR ENTANGLEMENT OF ENEMY PERSONNEL, LAYING COMMUNICATION WIRES OVER INACCESSIBLE TERRAIN, AND THE LIKE. THE WIRE IS INITIALLY TWISTED IN ONE DIRECTION TO PLACE A TORSIONAL STRESS THEREON. IT IS THEN HEATED AND QUENCHED TO PROVIDE A PERMANENT SET TO THE WIRE WHICH IS THEN TWISTED IN AN OPPOSITE DIRECTION TO PLACE ANOTHER TORSIONAL STRESS THEREON WHICH SUPPLIES THE FORCE NECESSARY FOR EJECTING IT FROM THE GUN.

March 2, 1971 A. GRANDY, JR

METHOD OF MAKING WIRE GUN 2 Sheets-Sheet 1 Original Filed March 15, 1962 mm m mm m.

J W E R D N A March 2, 1971 A. GRANDY, JR

METHOD OF MAKING WIRE GUN 2 Sheets-Sheet 2 Original Filed March 15, 1962 INVENTOR. ANDREW J. GRANDY 3,566,504 METHOD OF MAKING WIRE GUN Andrew Grandy, Jr., 2707 Grant Ave., North Hills, Pa. 19038 Original application Mar. 15, 1962, Ser. No. 180,058, now Patent No. 3,470,861, dated Oct. 7, 1969. Divided and this application Mar. 28, 1969, Ser. No. 823,232

Int. Cl. B21f 35/00; B23p 13/00 US. Cl. 29-173 6 Claims ABSTRACT OF THE DISCLOSURE The invention described herein may be manufactured and used by or for the Government for governmental purposes without the payment to me of any royalty thereon.

This invention is a division of my pending application Ser. No. 180,058, filed Mar. 15, 1962, for Wire Gun, and now Pat. No. 3,470,861, relates to a hand held wire gun for projecting a length of about 100 wire feet and more quickly under the impetus of internal torsional stresses in the Wire, and has for an object to provide a simplified method, apparatus, and product for accomplishing this result providing a gun of this type suitable for quickly laying a wire entanglement,- or a communication wire laid over flat ground, or for throwing a wire across a chasm preparatory to erecting a bridge, and for a multitude of other uses.

FIG. 1 shows a use for this product in being able to shoot a wire across a chasm for communication uses, or preparatory to erecting a bridge.

FIG. 2 is a longitudinal partial section through one embodiment of this invention.

FIG. 3 is a left side view of the device of FIG. 2.

FIG. 4 illustrates a short length of untwisted Wire having barbs formed along at least one edge thereof.

FIG. 5 shows one method of making a supply reel filled with twisted wire from which internal stress has been relieved.

FIG. 6 shows a short length of twisted wire from which internal stress has been removed.

FIG. 7 exemplifies the manner of winding wire fiatwise when it contains enough internal stress for its intended use.

FIG. 8 illustrates a collapsible mandrel on which the wire under torsional stress may be wound fiatwise as in FIG. 7.

The length of wire shown in FIG. 1 is shot from a coil of the type in FIG. 2 under the impetus of internal torsional stress within the wire wound fiatwise to contain such internal stress.

This is accomplished by taking a supply reel 10 of soft untempered spring steel wire preferably of rectangular cross section and free of internal torsional stress as shown at reel 10 in FIG. 5. This wire should be of about a 1050 to 1095 carbon content and capable of being heat treated and quenched in a manner Well known in the United States Patent 0 art to have a Rockwell C hardness of about 38 to 45 with its elastic limit and ultimate strength greatly increased. The guide rolls 11 and 12 feed the untwisted soft spring wire between them from the reel 10 and function to prevent any later applied twist in the wire getting to the reel 10. The rolls 13 and 14 are preferably spaced from rolls 11 and 12 the pitch distance of a twist and rolls 13 and 14 have their axes rotated around the wire at a rate depending on the speed of the wire. This rotation may be by hand but preferably by mechanism geared to the drive for the wire from rolls L1 and 12. The degree of twist is preferably at a rate to impose a torsional twist upon the wire which is well above its elastic limit leaving a permanent set on the soft wire.

Within the rectangle 15 is an appropriate heater for the wire after which it is promptly quenched to harden it and raise its elastic limit and ultimate strength far above what it was previously in its untempered condition. This conventional heat treatment is familiar to those skilled in the art who know that any remaining torsional stress in the wire 16 from twisting rollers 13 and 14, is removed by the twisting and tempering. After this heat treatment the twisted but torsionally unstressed wire 17 is wound up on reel 18.

The twisted wire 17 is unsuitable for use in the wire gun of FIG. 1 for two reasons. It is not stressed and it is of a shape not adapted to be wound compactly in a coil. To eliminate these disadvantages they are now harmonized into a shape that may be compactly wound as well as possessed of substantial internal stress in torsion.

For that purpose the same reel 18 from FIG. 5 after being filled is transferred to a support 19 (FIG. 7) mounted on a bearing 20 capable of allowing the reel axis to be rotated in a plane generally normal to that of the wire and through the reel axis so that torsional stress applied to wire 17a may enable the reel 18 to rotate about the axis of its stem 21 in the bearing 20. It should be borne in mind that the twisted unstressed wire 17a coming from reel 18 is the same as that which is designated 17 in FIG. 5 as being wound upon reel 18. The first pair of straightening rolls 22 and 23 (FIG. 7) preferably pull the wire from reel 18 and feed it toward the mandrel 26 on which the torsionally stressed wire is wound fiat-wise. The second pair of straightening rolls 24 and 25 rotate in the plane of their axes to untwist the wire applying torsional stress in doing so and are located closely adjacent the wind-up mandrel 26. These rolls 24 and 25 are preferably spaced apart as were the first pair of straightening rolls 22 and 23 or an amount equal to about a full twist so as to be spaced apart a distance enough to afford any of the torsional stress being put in the wire, a chance to make the wire become untwisted but restressed torsionally for Winding fiat on mandrel 26 without weakening any of the torsional stress. This restressing in torsion by unt-wisting the unstressed wire 17a is in value about half of the elastic limit of the tempered wire. This in pounds per square inch may exceed the stress imposed on the wire 16 due to the higher elastic limit imparted to the wire 17a by the heat treatment and quenching.

In FIG. 6 is shown a specimen of the wire 16 before being untwisted by the straightening rolls 22 to 25 inclusive. In this figure of the drawing the degree of twist is sufiicient to have one full twist i.e. from a peak on one edge to a next peak on an opposite edge, about 3 inches. This wire is about .025 inch thick and .25 inch wide.

After winding a desired length of wire upon mandrel 26, the mandrel is removed from the wound wire and from the shaft 27. This mandrel 26 is shown in FIG. 8 as being in four parts, 49, 50, 51, and 52 mounted on shaft 27, and capable of being slid longitudinally ofi? this shaft. When these four segments are assembled on shaft 27 an elastic band not shown adjacent each end will hold these segments in place, such bands passing around the tying cords or straps 53 placed within the grooves illustrated. In starting to wind the torsionally stressed wire flatwise on the mandrel an end is given a short 90 bend 40 and placed within a slot in one end portion as shown. When a desired length has been wound the tie cords 53 are made fast to their opposite ends over'tlie top "of wound wire to then able to be slid longitudinally off the shaft 27 leaving the coiled and stressed wire held together for insertion into one end of the housing 29 described later and shown in FIG. 2. The inner end 40 is placed in a notch 38 in the dart 34 before the coil is inserted into housing 29. After being inserted into the housing the tie cords may be cut and pulled out longitudinally from around the coiled wire and the end of the housing.

This housing 29 is of light weight material such as aluminum or plastic into which the coil convolutions may be slid. It has an end closed by a cap 30 clamped between two nuts 31 and 32 threaded on the light metal guide tube 33 in which is received the rear end of a dart rod 34 and a firing pin 35 secured to the dart by the somewhat .S shaped connection 48 illustrated. In this way when the firing pin 35 is pulled back far enough, the right end of pin 35 becomes disconnected from the dart 34, allowing a small helical spring 36, engaging the front end of tube' 33 and a head or forward end 37 of the dart, to be compressed and then released ejecting the dart 36 forward. A notch 38 receives an inner end of the torsionally stressed wire coil. Any notched rod may serve to carry the inner end 40 of the wire coil out of the housing for freeing the Wire end 40 and allow the stressed wire to be relieved forcing the wire forward as the stress in the wire becomes freed in successive convolutions. The housing wall 41 is of foam rubber to assist in guiding the wire being ejected through the hole shown as being larger than the dart 34 and its head 37. In front of housing 29 and its wall 41 is an extension 42 filled with material such as excelsior or sawdust or the like capable of nevertheless exerting a slight retaining effect upon the convolutions, to protect against coil damage under shocks in handling. The light cap 43 closes the front end of the extension and a pull-01f type tape 44 holds the cap in place on the front end of extension 42 of the housing 29. The cap 43 is of light enough material to be punctured by the dart in event cap 43 is not removed and has been forgotten. A soft metal safety pin 45 of the general shape shown in FIG. 3 looks the pin 35 and spring 36 against being compressed by pulling ring 46 until after this safety pin 45 has been removed from its cooperation with the groove illustrated in the firing pin 35.

In FIG. 4 is shown another type wire having barbs 47 formed by stamping along at least one edge of the wire and for use in quickly laying barbed wire entanglements for their usual uses in impeding movements of personnel. In the embodiment of FIG. 4 the wire is about .024 inch thick, about .250 inch in width including the barbs, and is twisted, heated, treated, and untwisted in applying torsional stress to the wire as described above.

The wire described when stressed during untwisting to only about half its elastic limit in torsion has been found to be capable of throwing the initially ejected end of the wire a distance of about 100 feet at a rate of about 100 feet per second. After removal of the safety pin 45 and pulling ring 46 away from the operators other hand holding the housing 29, the dart is ejected and starts ejection of the wire. The dart or other rod falls in a few feet while the wire continues and may be used for throwing a communication wire or a wire for initially pulling a heavier wire across a chasm or depression as shown in FIG. 1. Where the ground is fiat this invention is useful in quickly laying a message wire. Such a wire should be insulated with a layer only about .001 of an inch thick of a well plasticized plastic or an enamel applied after heat treatment and before winding on the mandrel.

Among the advantages of this may be mentioned the ability to quickly and easily lay wire entanglements and wire for communications with a range of about 100 feet with a velocity of to 100 feet per second. These values are not believed to 'be upper limits because thicker wir should enable greater ejecting force to be available. Any shape of wire cross section may be used but the wire of rectangular cross section has the advantage of showing the degree of its permanent set when twisted and when untwisted enablesthe wire to be compactly wound for storage, ready for use as a wire gun or for many other purposes. The housing is light in weight, as a dispenser of wire entanglement this wire is said to have a psychological effect upon impact of the leading inner end of a coil upon personnel. Where barbed wire has heretofore been said to obstruct approach troops, this improvement may be caused to surround and attach to moving troops. The outer end of the torsionally stressed wire coil needs no special holding as does the inner end of the coil but will be adequately secured when the coil snugly slides into the housing 29. The degree of Rockwell C hardness after tempering determines an elastic limit much more than double the wire strength when soft and before tempering. Space economy in winding the stressed wire flatwise is an important feature of this invention product.

A plurality of wires may be simultaneously ejected from a plurality of windings. A plurality of wires may be simultaneously wound and ejected from the same coil simultaneously with the wires nested.

I claim:

1. A method of forming a coil of spring wire with one end to be ejected from the coil longitudinally and generally axially under the impetus of internal torsional stress within the wire, said method including twisting said wire under torsional stress, removing the torsional stress from said wire without entirely untwisting it, twisting said wire oppositely to its first twist under torsional stress below its yield point, winding the torsionally stressed wire into a coil, and securing the inner and outer end of said coil against automatically uncoiling.

2. A method according to claim 1, in which the first application of torsional stress is to an amount above the yield point of the wire, said wire being of spring steel, and removal of the torsional stress without the wire becoming fully untwisted is accomplished by the application of a torsional stress beyond the elastic limit of the wire and a tempering heat and quenching to enhance the strength of the wire.

3. A method according to claim 2 in which said wire is initially generally rectangular and having a width at least several times its thickness and the second and opposite twisting substantially flattens the wire for winding.

4. A method according to claim 3 in which is wire of spring steel known as RC38-45 in about the 1050 to 10 carbon range, said wire being wound fiat after said untwisting but containing an internal stress in torsion below its elastic limit, whereby on release of the inner end of said coil its convolutions are successively ejected generally axially.

5. A method according to claim 4 in which said reapplication of torsional stress occurs close to the place at which said winding occurs and the removal of torsional stress takes place largely during the initial application of torsional stress.

6. A method of claim 3 in which the inner end of said wound coil is ejected generally axially and longi- 5 tudinally with an ejection of an axial stern, and after winding the Wire upon a form, collapsing said form and removing said form from the coil while securing the inner end of said coil against unwinding.

References Cited UNITED STATES PATENTS 1,934,122 11/1933 Hill 140-149X 2,370,036 2/1945 Howell 29-415X 6 3,181,524 5/1965 Bratz 124-16 3,465,743 9/1969 Gilmore et al 124-18 JOHN F. CAMPBELL, Primary Examiner 5 V. A. DI PALMA, Assistant Examiner US. Cl. X.R. 

